The invention relates to a line for manufacturing packagings (2) producing folding boxes (CA1, CA2) from plate elements (4), which comprises a feeding station (20), a shaping unit (33) which consecutively shapes the plate elements (4) by slitting, scoring and cutting operations, provided with pairs of shafts (230.sub.a-233.sub.a, 230.sub.b-233.sub.b) and a cutting unit (24), which engage to produce, in the shaped plate element (3), two juxtaposed folding box layers (P1, P2), arranged transversely to the direction of transport (FD), which are associated in series, and connected to one another by attachment points (45), a folding/gluing unit (26) which forms folded assemblies (5) by folding and gluing the shaped plate elements (4), a counting/ejection unit (27) which forms stacks of folded assemblies (6, 7), and a unit (29) for separating folding boxes comprising means arranged to produce, by breaking the attachment points (45), two separate batches (8.sub.1, 8.sub.2) of stacked folding boxes from each stack of folded assemblies (6, 7).

The present invention relates to a transfer module (26) for a folder-gluer machine (1), the transfer module comprising a lower conveyor (36) and an upper conveyor (38) adapted to receive a folding box (2) therebetween and to transport the folding box in a direction of transportation (D) towards a downstream-located loading surface (90) in a stacker module. The upper conveyor (36) of the transfer module extends further in the direction of transportation than the lower conveyor (38) and the lower conveyor comprises a first conveyor belt (38a) and second conveyor belt (38b), each having an inlet end (67a, 67b) and an outlet end (65a, 65b), and wherein the outlet ends are displaceable in the direction of transportation.

A feeding device for feeding stacks of standing flat-folded cartons to a receiving station, comprising a conveyor track having a flat bearing plane adapted to support the stacks, where the conveyor track comprises at least two rows of teeth where each row of teeth comprises a plurality of spaced apart teeth adapted to support the stacks of flat-folded cartons, where the teeth can be positioned in either an erected position or in a folded position, and where the feeding device comprises a guide track arranged along the bearing plane adapted to hold the teeth in the selected position, and where the guide track ends at an end region of the conveyor track, such that the teeth are unsupported at the end region. The advantage of the invention is that stacks of flat-folded cartons can be merged continuously at an outfeed region.

Arrangement for cutting notches in box blanks fed along a feeding direction. A feeding portion feeds box blanks. At least a first-fourth cutting devices along the feeding direction. The first is arranged most upstream and the fourth is arranged most downstream. Each device includes: a first wheel rotating around a first axis transverse to the feeding direction, the first wheel being on a first side of the blanks; a second wheel rotating around a second axis extending transverse to the feeding direction parallel to the first axis, the second wheel being in the same plane as the first wheel on an opposite side of the blank; and a cutting element cutting notches. The cutting element extends from either the first or the second wheel towards the other. A control unit controls the operation of the first-fourth devices for different operation combinations.

The technology described herein generally relates to an automated packaging apparatus and system that packages loose particles into a conical container as well as the final packed containers. More specifically, loose plant matter, such as crumbled dried leaves, are supplied to successive paper cones. The apparatus provides a system for reliably and accurately depositing or injecting a fluid into a cone packed with loose particulate.

A converting assembly performs a plurality of conversion functions on sheet material to convert the sheet material into packaging templates. The converting assembly includes a plurality of tool rollers. Each of the tool rollers has one or more conversion tools thereon. The one or more conversion tools on an individual tool roller are configured to perform a subset of the plurality of conversion functions that convert the sheet material into packaging templates.

A printing unit includes a support frame that is supported to face a transfer passage for a sheet; an inkjet head that is fixed to the support frame and performs printing on a printing surface of the sheet; drive bodies that are rotatably supported on the support frame on both sides of the inkjet head in a width direction of the sheet and come into contact with the printing surface of the sheet; and a drive device that drives and rotates the drive bodies.

A printing unit includes a support frame that is supported to face a transfer passage for a sheet; an inkjet head that is fixed to the support frame and performs printing on a printing surface of the sheet; drive bodies that are rotatably supported on the support frame on both sides of the inkjet head in a width direction of the sheet and come into contact with the printing surface of the sheet; and a drive device that drives and rotates the drive bodies.

A line and method for the production of covered cardboard boxes are disclosed. The line includes a conveyor unit including a belt and a conveyor actuator that drives the belt intermittently in an alternating sequence of movements and stops. A feed unit individually feeds covering blanks from a reservoir to the conveyor unit in a sequence of feed instants. An erecting machine folds box blanks into corresponding boxes. A positioner individually positions the boxes from the erecting machine, in alignment on corresponding covering blanks disposed on the belt of the conveyor unit. A gluer spreads glue on one face of the covering blanks. A covering machine folds the covering blanks into contact with their respective boxes to cover the boxes. A control unit connected to the feed unit adjustably sets a phase displacement of the feed instants relative to the sequence of stops of the belt.

A system for automatically forming packaging boxes comprises a folding station comprising four folding units adapted to fold panels of cardboards blanks to form substantially cuboid boxes or lids or combinations of a box and a lid, some of said panels in the folded state forming pairs of two panels running substantially parallel to each other in a processing direction, in which the blanks are transported through the system, and orthogonal to a width direction of the blanks, which is the orthogonal direction to the processing direction in the plane of the blanks, one or more glue application units adapted to put glue on at least one panel of each of said pairs of two panels, a feeding conveyor to convey a cardboard blank into the folding station, a curing station adapted to take over the boxes or lids or combinations of a box and a lid folded in the forming station from the folding station, said curing station comprising holding structure to form-fittingly hold said pairs of panels and to guide the boxes or lids or combinations of a box and a lid through the curing station.